We study self-diffusion in complex fluids within dynamic density functional theory and explicitly account for the coupling to the fluctuating background. Applying the formalism to nematic and smectic liquid crystals, we find the temporary cages formed by neighboring particles to compete with permanent barriers in nonuniform systems, resulting in non-Gaussian diffusive motion that in different directions becomes correlated. Qualitative agreement with recent experiments demonstrates the importance of explicitly dealing with time-dependent self-consistent molecular fields
In paper II of this series we apply the center-of-mass version of Nonlinear Langevin Equation theory...
Abstract. We propose a computational method to simulate anomalous self-diffusion in a simple liquid....
Subdiffusion is commonly observed in liquids with high density or in restricted geometries, as the p...
We study self-diffusion in complex fluids within dynamic density functional theory and explicitly ac...
We study self-diffusion in complex fluids within dynamic density functional theory and explicitly ac...
We investigate the anomalous dynamics in smectic phases of short host rods where, counter-intuitivel...
International audienceWe investigate the anomalous dynamics in smectic phases of short host rods whe...
We consider the process of self-diffusion in the cellular structure in the presence of permeable bar...
Self-diffusion and radial distribution functions are studied in a strongly confined Lennard-Jones fl...
We provide a theoretical explanation for the observed quasiuniversality of the ratio of the longtime...
Molecular dynamics computer simulations have been conducted to examine the self-diffusion process fo...
Using dynamical density functional theory (DDFT), we theoretically study Brownian self-diffusion and...
We report a theoretical study of the variation of the self-diffusion coefficient across a liquid-cry...
We propose a computational method for simulating anomalous self-diffusion in a simple liquid. The me...
We provide a theoretical explanation for the observed quasiuniversality of the ratio of the long-tim...
In paper II of this series we apply the center-of-mass version of Nonlinear Langevin Equation theory...
Abstract. We propose a computational method to simulate anomalous self-diffusion in a simple liquid....
Subdiffusion is commonly observed in liquids with high density or in restricted geometries, as the p...
We study self-diffusion in complex fluids within dynamic density functional theory and explicitly ac...
We study self-diffusion in complex fluids within dynamic density functional theory and explicitly ac...
We investigate the anomalous dynamics in smectic phases of short host rods where, counter-intuitivel...
International audienceWe investigate the anomalous dynamics in smectic phases of short host rods whe...
We consider the process of self-diffusion in the cellular structure in the presence of permeable bar...
Self-diffusion and radial distribution functions are studied in a strongly confined Lennard-Jones fl...
We provide a theoretical explanation for the observed quasiuniversality of the ratio of the longtime...
Molecular dynamics computer simulations have been conducted to examine the self-diffusion process fo...
Using dynamical density functional theory (DDFT), we theoretically study Brownian self-diffusion and...
We report a theoretical study of the variation of the self-diffusion coefficient across a liquid-cry...
We propose a computational method for simulating anomalous self-diffusion in a simple liquid. The me...
We provide a theoretical explanation for the observed quasiuniversality of the ratio of the long-tim...
In paper II of this series we apply the center-of-mass version of Nonlinear Langevin Equation theory...
Abstract. We propose a computational method to simulate anomalous self-diffusion in a simple liquid....
Subdiffusion is commonly observed in liquids with high density or in restricted geometries, as the p...